The Science of BSE

BSE and vCJD are today classified as transmissible spongiform encephalopathies (TSEs), which are understood as rapidly progressive and fatal brain diseases affecting several mammalian species.Reference Prusiner, Collinge and Powell ³⁰ The oldest known TSE is scrapie, a disease of sheep first identified in the 18th century. Beginning in the 1980s, American neuroscientist Stanley Prusiner had argued for the causal role of the prion protein in the TSEs, rather than the “slow viruses” that had been implicated for much of the 20th century. The prion occurs naturally in the central nervous system of many species, performing an as-yet unspecified function. Prusiner argued that TSEs arise when the prion obtains a misfolded shape that is then transmissible to other prions.Reference Ellison, Love, Chimelli, Harding, Lowe and Vinters ³¹ Through this mechanism, TSEs can be spread between individuals and across the species barrier. Despite facing much opposition, Prusiner’s theory was ultimately proven right, and he was awarded the 1997 Nobel Prize for Physiology or Medicine at the height of the British BSE crisis.

At the pathological level, prion diseases are associated with the aggregation of an abnormal prion protein (termed PrPSc) in the brains, spinal cords, and lymphoreticular tissue of affected individuals. These PrPSc particles appear resistant to common decontamination procedures. The aggregates of misfolded protein seen in many TSEs, including Creutzfeldt-Jakob disease (CJD) and vCJD, bear a certain resemblance to the proteinaceous inclusions found in Alzheimer’s disease.Reference Armstrong, Cairns, Ironside and Lantos ³² Following the BSE crisis, this similarity was used to support a hypothesis linking beef consumption to the development of Alzheimer’s disease.Reference Waldman and Lamb ³³ However, a lack of concrete evidence and several notable differences between the diseases has led to the ultimate dismissal of this notion.Reference Waldman and Lamb ^{34 ,} Reference McIlroy and Picard ³⁵

The most common human TSE is CJD, occurring with an incidence of approximately 1 per million per year. CJD was first described in the 1920s by German neuroscientists Hans Gerhard Creutzfeldt and Alphons Maria Jakob. Mean survival is 4-8 months; 90% of patients are dead within 1 year. The peak age of onset is 55-75 years. The diagnosis is firmly established through autopsy, though characteristic changes on magnetic resonance imaging scan and electroencephalography are highly sensitive and specific.Reference Geschwind ³⁶ CJD may arise in a familial or sporadic pattern, and is now understood to reflect patients’ genetic variability. Hereditary and sporadic CJD reflect mutations at codon 129 in the prion protein gene.Reference Ellison, Love, Chimelli, Harding, Lowe and Vinters ³¹ Similarly, it appears that sensitivity to BSE exposure reflects homozygosity for methionine at codon 129 of the host’s prion protein gene, in that all cases of vCJD have demonstrated this genotypic pattern.Reference Mastrianni ³⁷

Beginning in 1993, a new clinical syndrome reminiscent of CJD was identified among young people in Britain.Reference Will, Ironside and Zeidler ¹² This syndrome was later named vCJD, and is characterized by prominent behavioral features, ataxia, dementia, and ultimately death. The age of onset of vCJD is much younger than classical CJD, typically affecting those in their teens and 20s. The course of vCJD is relatively prolonged, with death occurring after a mean of 14 months. Diagnostic findings of vCJD on magnetic resonance imaging and electroencephalography are distinct from CJD.Reference Geschwind ³⁶ As of 2014, there have been 229 cases of vCJD worldwide, mostly in the United Kingdom; two cases have been reported in Canada. ³⁸ It is now understood that vCJD reflects the transmission of BSE to humans via the consumption of infected beef.Reference Almond and Pattison ^{13 ,} Reference Bruce, Will and Ironside ^{39 –} Reference Buschmann and Groschup ⁴³

BSE and vCJD in Britain, 1984-1996

The origins of the BSE crisis in Britain have been traced to Sussex in December 1984, when a cow fell ill with a new clinical syndrome: tremor and incoordination rapidly leading to death. Within a few months, cows from all across Britain had succumbed to a similar constellation of symptoms. The total number of cows affected in Britain likely exceeded 1 million.Reference Philips, Bridgeman and Ferguson-Smith ¹¹ The rapid spread of BSE across the country is now attributed to the agricultural system of rendering, in which protein is extracted from nonmuscular sources called offal, and is then incorporated into human or animal food as meat and bone meal (MBM). Although it is unclear how BSE first arose in Britain’s cattle, a strong body of evidence suggests that the rendering of affected cattle allowed for the dissemination of infected MBM across Britain. In essence, cow protein containing BSE was fed back to cows, cannibalizing a herbivorous species and creating an ideal route of transmission for a prion disease.Reference Smith ²

The first official pathological analysis of cattle with BSE was produced in 1986 by Raymond Bradley of England’s Central Veterinary Laboratory. Bradley characterized the features of BSE as sharing “similarities to spongiform encephalopathies of other species and in particular scrapie of sheep.”Reference Philips, Bridgeman and Ferguson-Smith ¹¹ As demonstrated by his initial report and by subsequent British policy decisions, the significance of the discovery of this new disease was immediately apparent. In that initial report, Bradley wrote:

Bradley’s report, the first government document discussing a spongiform encephalopathy of cattle, exemplifies a set of interwoven themes that came to dominate the story of BSE in Britain.Reference Shamy ⁴ BSE was assumed to reflect the spread of scrapie to cattle, and therefore it was not expected to be transmissible to humans. As a consequence, animal health experts, and not medical professionals, directed the management of BSE in Britain. And although the potential significance of BSE for human health was immediately apparent, medical concerns were considered secondary to BSE’s immediate economic and political ramifications.

Because BSE was thought to reflect the infection of cattle with scrapie, which had never been known to cross the species barrier, scientists and policymakers repeatedly stated that BSE would pose no risk to humans.Reference Philips, Bridgeman and Ferguson-Smith ¹¹ This conclusion was questioned scientifically as early as 1990, when pathological analyses demonstrated different histological properties and patterns of transmission for BSE and scrapie. However, the association between BSE and scrapie was not officially tested by scientists at Britain’s Ministry of Agriculture, Fisheries and Food (MAFF) until 1996. In March 1996, the Secretary of State for Health, Stephen Dorrell, announced to Parliament the results of investigations performed by a separate group of physicians and epidemiologists who had concluded that the first cases of vCJD reflected the transmission of BSE to humans.Reference Warden ⁴⁴

Despite denying the existence of a risk to humans up until 1996, British policies implicitly recognized that human infection was a possibility.Reference Miller ²⁹ In fact, the British government’s continued assurances undermined the implementation of its own policies.Reference Jacob and Hellström ¹⁶ For example, a series of measures were put in place between 1988 and 1990 to limit exposure to the highest risk tissues from infected cattle, what British agencies termed specified bovine offal (SBO). Though legislation banned SBO from human consumption in June 1989, cattle farmers were given 5 months to dispense of their stock into the human food chain. Surveillance was difficult, and penalties for including SBO in processed meats were minimal. In March 1995, surveillance by MAFF veterinarians found that 48% of abattoirs and slaughterhouses were not fully complying with regulations to keep SBO out of human foodstuffs.Reference McKee, Roberts and Lang ⁴⁵ Ultimately, slaughterhouses did not feel compelled to exclude SBO from processing because the government had repeatedly reassured the nation that BSE would pose no risk to humans.

The inconsistencies and contradictions inherent in the British government’s policies reflect a state of scientific uncertainty superimposed upon an administrative structure that was biased toward the interests of the cattle industry.Reference Miller ²⁹ Miller has argued that risk disputes like those surrounding BSE “are disputes over matters of interests and the distribution of resources… ideology is the crucial attendant of such controversies.”Reference Miller ²⁹ MAFF was charged with both maintaining food safety and advocating for the agricultural industries, two tasks that were in conflict during the BSE era. Following the election of Margaret Thatcher’s Conservative government in 1979, MAFF had advocated for free market practices and industrial self-regulation within the agricultural sector, which arguably had contributed to the rise of BSE and had certainly impacted its management.Reference Von Zwanenberg and Millstone ¹⁸ For example, MAFF sought to prevent panic surrounding BSE, a goal it achieved by banning the publication of information about BSE for 6 months after its initial description.Reference Carr-Brown and Boztas ⁴⁶ Government officials could not speak to the media about BSE without first seeking approval from MAFF. All BSE-tested cattle brains became MAFF property and were withheld from independent researchers.Reference Von Zwanenberg and Millstone ¹⁸

Critics of Britain’s management of BSE have argued that from 1986 to 1996 the government failed at assessing, managing, and communicating the (as-yet uncertain) risks posed by BSE for the people of Britain.Reference Carr-Brown and Boztas ⁴⁶ In light of these conclusions, the Canadian experience with BSE can serve as an important contrast to British management, with relevance for Canadians but also for governments around the world. How did Canada’s policies reflect the improved state of knowledge within the scientific community in the early 2000s? How did Canada balance private and public interests in its handling of BSE? In short, did Canada improve on British policies or replicate its mistakes?

BSE and vCJD in Canada, 1990-2014

As in Britain, Canada’s experience with BSE can be analyzed from the perspective of risk assessment, management, and communication.Reference Haines ⁴⁷ In this article, we are most interested in the way risk assessment was implicitly reflected in management and communication decisions. In the aftermath of the British experience, we are sensitive to the way risk assessment expressed in official government statements and documentation may not reflect the logic of enacted policies or vice versa. Importantly, analysis of risk assessment and management needs to be appropriately historicized: namely, policies and practices are most fairly understood in reference to the state of knowledge in their time and place.

The world learned of BSE as a cattle disease in the late 1980s, and its meaning for public health (suggested as early as 1986) became clear by 1996. Therefore, for most of the period in question here, BSE was known to be a disease of cattle that could be transmitted to humans with devastating consequences. Uncertainty surrounding the question of whether BSE could cause human disease was, as of 1996, no longer justifiable: a series of experiments conducted in cattle, sheep, cats, and humans had demonstrated that BSE and vCJD were pathologically identical to each other and distinct from other TSEs.Reference Bruce, Will and Ironside ⁴⁸ Therefore, claims that the discovery of BSE in Canadian cattle “created unmanageable uncertainty”Reference Charlebois ⁴⁹ must be reframed: the discovery of BSE in Canada established with certainty that a previously theoretical public health risk was now present in Canada and would have to be addressed appropriately. We contend that this did not occur, in that the Canadian government appears to have failed to appreciate the implicit public health implications of BSE. Policies were delayed and incomplete in their implementation, biased toward the beef industry thereby placing human health in danger. That this danger has not been reflected in human disease is gratifying but should not be seen as proof positive of effective policies.

Canada’s management of BSE began in 1990, when it made BSE a reportable disease. ⁵⁰ Though no cases of BSE were known to exist in Canada at that time, reportable status meant that any cow diagnosed with BSE would be required to be withheld from the food supply and reported to government agencies. The identification of BSE as a reportable disease at this stage reflected an appropriate level of concern on behalf of federal regulators; should BSE be found in Canada, it would justifiably be an issue to be addressed by governmental agencies. The responsibility for BSE surveillance and testing was eventually centralized under the auspices of the CFIA in 1997.

Canada’s surveillance program is, and was from its outset, voluntary, or “passive” in that diagnostic testing is only initiated if BSE is suspected on clinical grounds. At no point did Canada require random testing for BSE as exists in Japan, nor has there been routine testing of cattle above a certain age, as is done in the European Union.Reference Leiss, Tyshenko and Krewski ¹⁷ Therefore, for a Canadian cow to be tested, its owner would need to identify one of a certain set of agreed-upon clinical features that may point to BSE. Specifically, tested cattle are those that are found dead, seem to be diseased or dying, or “downers,” meaning that they can no longer stand. The owner must then alert a local veterinarian to obtain a sample of the cow’s brain, thereby killing the cow. During the period of testing—which now takes only days—the cattle would have to be stored and eventually disposed of. Canada tests approximately 30,000 cattle per year, a number in accordance with guidelines established by the World Organization for Animal Health (OIE) on the basis of Canada’s cattle population. ^{51 , 52}

The logistics of BSE testing are important and continue to reflect a major source of controversy in Canada. We propose that the Canadian surveillance system for BSE is biased against testing, a circumstance that echoes the British experience. Although cattle farmers are provided compensation if a cow is found positive for BSE, ⁵³ the act of testing still risks a financial loss for producers and processors.Reference Mussel, Grier and Schmidt ^{54 , 55} Cattle producers report significant stigma associated with the reporting BSE-positive cattle.Reference Dunn ⁵⁶ The Canadian Cattlemen’s Association continues to engage in public relations campaigns encouraging testing, ⁵⁷ which demonstrates the tendency against testing in the industry (see Figure 1). Moreover, in private communication with the Canadian Cattlemen’s Association, we were informed that rates of testing appear to fluctuate with the market value of cattle (personal communication with Rob McNabb, December 3, 2014). This observation suggests the impact of the economic disincentives built into the Canadian surveillance system: when the auction value of the cow is highest, the loss produced by sending it for testing is greatest, and therefore the impetus to test is at its nadir. Therefore, cattle that would meet the criteria for testing may not always be sent for testing, indicating how an already passive system ⁵⁸ remains porous to potentially affected animals.

Figure 1 Test me for BSE. Image courtesy of Agriculture Alberta. Accessed online at: http://www1.agric.gov.ab.ca/$Department/deptdocs.nsf/All/cpv15105.

Though the CFIA notes that its protocols are in accordance with guidelines set by the OIE, this assertion is not entirely true. When the OIE performed a review of Canada’s management of BSE in 2004, it suggested the implementation of an expanded surveillance protocol that would include non-cattle from farms at risk, a suggestion that was never adopted by the CFIA.Reference Forge and Fréchette ⁵⁹ A 2004 report by the Attorney General of Ontario addressing issues of meat safety argued for the use of both passive and active (i.e. routine) surveillance to ensure a comprehensive risk management system.Reference Haines ⁴⁷ Furthermore, although the numbers of cattle tested are in accordance with the OIE, there is ultimately no penalty for not reaching those targets. Moreover, because Canada has never performed routine surveillance to establish an accurate incidence of BSE among its cattle herds, it is difficult to know whether the targets suggested by the OIE on the basis of herd size are appropriate for the Canadian population. Finally, there is currently no way of knowing whether the right cattle are being tested, by which we mean that cattle with BSE may be voluntarily or involuntarily excluded from testing. ^{51 ,} Reference Dunn ⁵⁶ Therefore, subclinically affected cattle may still be reaching the slaughterhouse.

The first cow to test positive for BSE was discovered in Alberta in 1993. This cow had been imported from Britain in 1987, a practice Canada later banned in 1990.Reference Aldy and Viscusi ²⁸ Canada’s first BSE-infected cow was slaughtered, along with its herd mates and all other cattle that had been imported from the United Kingdom after 1982. The year 1982 was selected in light of a set of assumptions that had informed British policies about the origins of BSE—namely, that the BSE crisis had started in 1987, and that BSE’s incubation period would be no longer than 5 years. However, these assumptions were already in question by the early 1990s and were subsequently rejected after more extensive research.Reference Shamy ⁴ Ultimately, slaughtering older cattle would have had little impact because cattle imported from Britain before 1982 would likely have already entered the food chain by 1990. However, the point to be made is that Canada’s culling policies were based on scientific data that were already out of date.

Canada’s response to the first case of BSE within its borders focused on minimizing “external challenge” (i.e. the spread of BSE to Canadian herds from imported cattle) while failing to consider “internal challenge” (i.e. the possibility that BSE existed in, or might later arise from, native Canadian cattle).Reference Leiss, Tyshenko and Krewski ¹⁷ Policies assumed that Canada’s BSE-infected cow had acquired the disease in Britain and that BSE could not be spread to other cattle. As a consequence, further risk management measures (such as enhanced surveillance or stricter controls on rendering) were believed unnecessary. Though the causal role of rendering in the spread of BSE was strongly suspected by 1993,Reference Anderton, Collinge, Powell and Prusiner ⁶⁰ this practice continued unabated in Canada.

In May 1994, the Animal, Plant, and Food Risk Analysis Network (APFRAN), a division of the CFIA, completed a formal risk assessment of BSE in Canadian domestic herds.Reference Le Roy and Klein ²² APFRAN’s 1994 report echoed the early years of the British BSE crisis, in that it predicted that the economic impact of any indigenous cases of BSE would be “high.”Reference Leiss and Nicol ²³ This analysis was reminiscent of the 1986 report by British pathologist Raymond Bradley, in which he had stated that a BSE “would have severe repercussions to the export trade and possibly also for humans.” To limit panic, Bradley had suggested that his report be kept confidential.Reference Philips, Bridgeman and Ferguson-Smith ¹¹ Similarly, APFRAN’s 1994 report on BSE in Canada was withheld from the public and was only discovered by journalists through an Access to Information request in 2001.

The APFRAN report explicitly considered the possibility that BSE might have been disseminated into Canadian cattle feed through rendering, as had occurred in Britain. This is significant for two reasons: first, the APFRAN report went beyond the government’s stance in considering BSE an “external” threat and accepted it now as an “internal” issue; second, it demonstrates that Canadian scientists were aware of the role of rendering in the spread of BSE at least as early as 1994.Reference Le Roy and Klein ²² Restrictions on rendering at this early stage might have represented an important step in limiting any potential dissemination of BSE among Canadian-born cattle. Ultimately, the rendering of cattle continued in Canada until 1997, when the human health implications of BSE in Britain became a political issue that the federal government could no longer ignore. The notoriety of the BSE crisis in Britain, and its link to vCJD, prompted the Canadian government to impose a ban on the feeding of ruminant tissues to other ruminants. In this way, we see Canadian policy responding to the novel scientific landscape produced by the assured association between BSE and vCJD, though the role of rendering in the spread of BSE, and the presence of BSE in Canada, had been known years earlier.

Canada’s 1997 ban on the use of rendered cattle as meat and bone meal in cattle feed was an inadequate risk control measure, in that MBM continued to be used in the feed of poultry, pork, and domestic animals.Reference Labreque and Charlebois ⁶¹ Because cattle could still be fed to other livestock, and other livestock could still be fed to cattle, an indirect means for the transmission of BSE among cattle remained. In addition, no surveillance existed to prevent cross-contamination at feed mills. Moreover, Canada’s 1997 ban allowed for the continued use of existing feed stock, recalling British policies that had allowed farmers to use up feed stock after their equivalent ban a decade earlier.Reference Leiss, Tyshenko and Krewski ¹⁷ Albeit arbitrary, once a particular product has been deemed a risk, continued exposure becomes difficult to justify from a political and public health perspective.

In 2002, the CFIA carried out a more extensive risk assessment on the question of BSE in Canada. The CFIA report concluded that the 1997 MBM ban had resulted in a “negligible probability” that BSE had taken hold in Canada. However, the CFIA also commented that, should this assessment be proven incorrect, the consequences would be severe.Reference Carlberg and Brewen ⁶² As in Britain, the “consequences” with which the CFIA was concerned were political and economic in nature, with only one oblique reference to human health. The language of the CFIA report again implied that BSE, were it to arise, would be an “external” threat, and that spontaneous BSE would not be expected to occur among Canadian cattle.

In May 2003, 2 months before the CFIA report was published, the first native Canadian case of BSE was discovered. In response, 2700 herds of cattle were slaughtered.Reference Le Roy and Klein ²² Compounded by the discovery of an Alberta-born, BSE-infected cow in Washington state, the Canada-United States border was closed to Canadian beef exports. Thirty-three other countries subsequently banned live cattle and beef products from Canada. Economic damage to the Canadian cattle industry was on the order of $11 million per day, totaling $5.5 billion over 4 years. ⁶³ Prompted by economic rather than by health concerns, the Canadian government channeled $460 million to cattle producers through various federal and provincial programs and began offering compensation for the slaughter of cows. Compensation was determined on a sliding scale, to a maximum of $320 per animal, approximately one-quarter of previous market value.Reference Boyd, Jardine and Dreidger ⁶⁴ As in Britain (where farmers were provided 50% of the value of animals), low rates of compensation gave farmers little incentive to report and slaughter potentially affected animals.Reference Jacob and Hellström ¹⁶ Officials and politicians promoted the safety of Canadian beef, despite the absence of evidence to support such claims. The likelihood of finding additional infected cows in Canada was declared “insignificant,” until new cases arose. ⁵⁸ Since 2003, an additional 19 cases of BSE have been discovered in Canadian-born cattle, with the most recent case identified in February 2015. Assertions that cows could not develop the disease if they were younger than 30 months of age were also proven incorrect. As in Britain, the Canadian public was repeatedly reassured that the government had the situation under control.Reference Boyd, Jardine and Dreidger ⁶⁴ Prominent government figures made a show of eating beef, including then-Prime Minister Jean Chrétien. Thirteen years earlier, British Agriculture Minister John Gummer had famously appeared on television at the height of Britain’s BSE crisis to feed his daughter a hamburger (see Figures 2 and 3). ^{65 , 66}

Figure 2 Prime Minister Chrétien eating steak in the midst of Canada’s BSE crisis. Image courtesy BBC website (http://news.bbc.co.uk/2/hi/americas/3050455.stm).

Figure 3 British Agriculture Minister John Gummer and his daughter eat hamburgers during the British BSE crisis. Image courtesy BBC website (http://news.bbc.co.uk/2/hi/uk_news/369625.stm).

In response to the discovery of the two BSE-infected Canadian-born cattle, all specified risk materials (SRM)—those tissues most likely to contain BSE such as brains, spinal cords, and distal ileum—were prohibited from entering the human food chain.Reference Leiss, Tyshenko and Krewski ^{17 , 67} Before 2003, the government had considered Canada to be “BSE-free,” despite the discovery of a BSE-positive cow ten years earlier, and despite available knowledge about the role of rendering in BSE’s transmission. From 1990 to 2003, only the SRM from the one cattle with diagnosed BSE had been excluded from processing, allowing SRM from infected but asymptomatic, or simply untested, cattle to have entered the human food supply. The prohibition of all SRM from entering the food chain was enacted in 2003 as an attempt to guarantee that BSE could not pass to humans. Organs that had the potential to harbor BSE, even from potentially yet undiagnosed cattle, would therefore be excluded from consumption.

The Canadian ban on SRM parallels the British measure to remove all SBO from the human food chain, a decision that had been taken in Britain in June 1989. As in Britain, this prohibition was introduced without immediate effect, allowing cattle producers to continue to use SRMs in the human food chain for a further month after the ban was announced. Assessment regarding compliance with this legislation is performed by the CFIA in the form of quarterly random checks at slaughterhouses. According to the CFIA, no Canadian facility has ever been found to be in contravention of this order (personal communication with Dr. Noel Murray, December 3, 2014), in stark contrast to the British and American experiences, where up to 50% of slaughterhouses were found to be noncompliant with similar requirements.Reference Aldy and Viscusi ²⁸

Four years later, in 2007, Canada instituted an enhanced feed ban, prohibiting the inclusion of ruminant materials (essentially, rendered cattle) in any form of animal feed. ⁶⁸ Although ruminant materials had been excluded from ruminant feed in 1997, for ten years the government had allowed the use of ruminant materials in feed for chickens, pigs, fish, and domestic animals. The production of some feed with ruminant parts, and some without, creates an environment for potential cross-contamination between different pools of feed. Moreover, other animals exposed to ruminant-containing feed could become a reservoir for BSE infection and cross-transmission. As early as 1990, domestic cats in Britain had been diagnosed with BSE presumably acquired from eating feed contaminated with cattle SRM.Reference Carr-Brown and Boztas ⁴⁶ Canada has no reported cases of BSE in non-cattle, but it is not testing for them because BSE surveillance measures do not include non-cattle. ⁵⁸

No cases of vCJD have been linked to exposure to BSE in Canada, though two patients with vCJD have been treated in Canada since 1990. The first case of vCJD was identified in 2002 in a patient who had immigrated to Canada from the United Kingdom in the early 1990s. It was assumed that he had contracted vCJD there and had only begun to exhibit symptoms after arrival in Canada because of the disease’s long incubation period. ⁶⁹ The second case occurred in 2011 in a patient who had immigrated from Saudi Arabia and had reportedly begun to exhibit symptoms before his immigration to Canada. The Public Health Agency of Canada has therefore concluded that the incidents have “no negative implications for the safety of the Canadian food supply” and “no secondary risks to the health of Canadians.” ⁶⁹ In addition, the Canadian government has enacted various policy measures to prevent the disease-causing prion protein from entering the Canadian blood supply. Most notably, these included the 1999 and 2000 deferrals of blood donations from individuals having visited the United Kingdom and France during the height of these regions’ BSE crises.Reference Wilson, Hébert and Laupacis ⁷⁰ Demonstration of the prion protein in human lymphoreticular tissue before the onset of symptoms in individuals infected with vCJD raises the potential for disease transmission in this manner.Reference Blajchman, Goldman, Webert, Vamvakas, Hannon and Delage ⁷¹ However, an ongoing study has not been able to demonstrate blood transfusion as a cause for vCJD development in any individuals who have succumbed to the disease in Canada or elsewhere.Reference Hewitt, LLewelyn, Mackenzie and Will ⁷²